LED lamp for producing biologically-corrected light

ABSTRACT

A light-emitting diode (LED) lamp for producing a biologically-corrected light. In one embodiment, the LED lamp includes a color filter, which modifies the light produced by the lamp&#39;s LED chips, to increase spectral opponency and minimize melatonin suppression. In doing so, the lamp minimizes the biological effects that the lamp may have on a user. The LED lamp is appropriately designed to produce such biologically-correct light while still maintaining commercially acceptable color temperature and color rending properties. Methods of manufacturing such a lamp are provided, as well as equivalent lamps and equivalent methods of manufacture.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.13/174,339, which is in turn a continuation-in-part of U.S. patentapplication Ser. No. 12/842,887, filed on Jul. 23, 2010, which areincorporated herein by reference in their entirety.

FIELD OF THE INVENTION

The present invention relates to light sources; and more specifically toa light-emitting diode (LED) lamp for producing a biologically-correctedlight.

BACKGROUND

Melatonin is a hormone secreted at night by the pineal gland. Melatoninregulates sleep patterns and helps to maintain the body's circadianrhythm. The suppression of melatonin contributes to sleep disorders,disturbs the circadian rhythm, and may also contribute to conditionssuch as hypertension, heart disease, diabetes, and/or cancer. Bluelight, and the blue light component of polychromatic light, have beenshown to suppress the secretion of melatonin. Moreover, melatoninsuppression has been shown to be wavelength dependent, and peak atwavelengths between about 420 nm and about 480 nm. As such, individualswho suffer from sleep disorders or circadian rhythm disruptions continueto aggravate their conditions when using polychromatic light sourcesthat have a blue light (420 nm-480 nm) component.

Curve A of FIG. 1 illustrates the action spectrum for melatoninsuppression. As shown by Curve A, a predicted maximum suppression isexperienced at wavelengths around about 460 nm. In other words, a lightsource having a spectral component between about 420 nm and about 480 nmis expected to cause melatonin suppression. FIG. 1 also illustrates thelight spectra of conventional light sources. Curve B, for example, showsthe light spectrum of an incandescent light source. As evidenced byCurve B, incandescent light sources cause low amounts of melatoninsuppression because incandescent light sources lack a predominant bluecomponent. Curve C, illustrating the light spectrum of a fluorescentlight source, shows a predominant blue component. As such, fluorescentlight sources are predicted to cause more melatonin suppression thanincandescent light sources. Curve D, illustrating the light spectrum ofa white light-emitting diode (LED) light source, shows a greater amountof blue component light than the fluorescent or incandescent lightsources. As such, white LED light sources are predicted to cause moremelatonin suppression than fluorescent or incandescent light sources.For additional background on circadian effects of light, reference ismade to the following publications, which are incorporated herein byreference in their entirety:

-   Figueiro, et al., “Spectral Sensitivity of the Circadian System,”    Lighting Research Center, available at:    http://www.lrc.rpi.edu/programs/lightHealth/pdf/spectralSensitivity.pdf.-   Rea, et al., “Circadian Light,” Journal of Circadian Rhythms, 8:20    (2010).-   Stevens, R. G., “Electric power use and breast cancer; a    hypothesis,” American Journal of Epidemiology, 125:4, pgs. 556-561    (1987).-   Veitch, et al., “Modulation of Fluorescent Light: Flicker Rate and    Light Source Effects on Visual Performance and Visual Comfort.

As the once ubiquitous incandescent light bulb is replaced byfluorescent light sources (e.g., compact-fluorescent light bulbs) andwhite LED light sources, more individuals may begin to suffer from sleepdisorders, circadian rhythm disorders, and other biological systemdisruptions. One solution may be to simply filter out all of the bluecomponent (420 nm-480 nm) of a light source. However, such a simplisticapproach would create a light source with unacceptable color renderingproperties, and would negatively affect a user's photopic response. Whatis needed is an LED light source with commercially acceptable colorrendering properties, which produces minimal melatonin suppression, andthus has a minimal effect on natural sleep patterns and other biologicalsystems.

BRIEF SUMMARY OF THE INVENTION

Provided herein are exemplary embodiments of a light-emitting diode(LED) lamp for producing a biologically-corrected light. In oneembodiment, the LED lamp includes a color filter, which modifies thelight produced by the lamp's LED chips, to increase spectral opponencyand minimize melatonin suppression. In doing so, the lamp minimizes thebiological effects that the lamp may have on a user. The LED lamp isappropriately designed to produce such biologically-correct light, whilestill maintaining a commercially acceptable color temperature andcommercially acceptable color rending properties. Methods ofmanufacturing such a lamp are provided, as well as equivalent lamps andequivalent methods of manufacture.

BRIEF DESCRIPTION OF THE FIGURES

The accompanying drawings, which are incorporated herein, form part ofthe specification. Together with this written description, the drawingsfurther serve to explain the principles of, and to enable a personskilled in the relevant art(s), to make and use an LED lamp inaccordance with the present invention. In the drawings, like referencenumbers indicate identical or functionally similar elements.

FIG. 1 illustrates the light spectra of conventional light sources incomparison to a predicted melatonin suppression action spectrum forpolychromatic light.

FIG. 2 is a perspective view of an LED lamp in accordance with oneembodiment presented herein.

FIG. 3 is an exploded view of the LED lamp of FIG. 2.

FIG. 4 is an exploded view of a portion of the LED lamp of FIG. 2.

FIG. 5 is an exploded view of a portion of the LED lamp of FIG. 2.

FIG. 6 is an exploded view of a portion of the LED lamp of FIG. 2.

FIG. 7 is an exploded view of a portion of the LED lamp of FIG. 2.

FIG. 8 illustrates an optimal transmission curve for a color filter inaccordance with one embodiment presented herein.

FIG. 9 illustrates the light spectra of conventional light sources incomparison to the predicted melatonin suppression action spectrum forpolychromatic light, as illustrated in FIG. 1, and further including thelight spectrum of an LED lamp in accordance with one embodimentpresented herein.

FIG. 10 illustrates an optimal transmission curve for a color filter inaccordance with one embodiment presented herein.

DETAILED DESCRIPTION OF THE FIGURES

The following detailed description of the figures refers to theaccompanying drawings that illustrate an exemplary embodiment of an LEDlamp for producing a biologically-corrected light. Other embodiments arepossible. Modifications may be made to the embodiment described hereinwithout departing from the spirit and scope of the present invention.Therefore, the following detailed description is not meant to belimiting.

FIG. 2 is a perspective view of an LED lamp (or bulb) 100 in accordancewith one embodiment presented herein. As shown in FIG. 2, LED lamp 100includes a base 110, a heat sink 120, and an optic 130. As will bedescribed below, LED lamp 100 further includes one or more LED chips anddedicated circuitry within LED lamp 100. LED lamp 100 has been designedto produce a biologically-corrected light. The term“biologically-corrected light” is intended to mean “a light that hasbeen modified to minimize or limit biological effects on a user.” Theterm “biological effects” is intended to mean “any impact or change alight source has to a naturally occurring function or process.”Biological effects, for example, may include hormone secretion orsuppression (e.g., melatonin suppression), changes to cellular function,stimulation or disruption of natural processes, cellular mutations ormanipulations, etc.

Base 110 is preferably an Edison-type screw-in shell. Base 110 ispreferably formed of an electrically conductive material such asaluminum. In alternative embodiments, base 110 may be formed of otherelectrically conductive materials such as silver, copper, gold,conductive alloys, etc. Internal electrical leads (not shown) areattached to base 110 to serve as contacts for a standard light socket(not shown).

As known in the art, the durability of an LED chip is usually affectedby temperature. As such, heat sink 120, and structures equivalentthereto, serves as means for dissipating heat away from one or more ofthe LED chips within LED lamp 100. In FIG. 2, heat sink 120 includesfins to increase the surface area of the heat sink. Alternatively, heatsink 120 may be formed of any configuration, size, or shape, with thegeneral intention of drawings heat away from the LED chips within LEDlamp 100. Heat sink 120 is preferably formed of a thermally conductivematerial such as aluminum, copper, steel, etc.

Optic 130 is provided to surround the LED chips within LED lamp 100. Asused herein, the terms “surround” or “surrounding” are intended to meanpartially or fully encapsulating. In other words, optic 130 surroundsthe LED chips by partially or fully covering one or more LED chips suchthat light produced by one or more LED chips is transmitted throughoptic 130. In the embodiment shown, optic 130 takes a globular shape.Optic 130, however, may be formed of alternative forms, shapes, orsizes. In one embodiment, optic 130 serves as an optic diffusing elementby incorporating diffusing technology, such as described in U.S. Pat.No. 7,319,293 (which is incorporated herein by reference in itsentirety). In such an embodiment, optic 130, and structures equivalentthereto, serves as a means for defusing light from the LED chips. Inalternative embodiments, optic 130 may be formed of a light diffusiveplastic, may include a light diffusive coating, or may having diffusiveparticles attached or embedded therein.

In one embodiment, optic 130 includes a color filter applied thereto.The color filter may be on the interior or exterior surface of optic130. The color filter is used to modify the light output from one ormore of the LED chips. The color filter modifies the light so as toincrease spectral opponency, and thereby minimize the biological effectsof the light, while maintaining commercially acceptable color renderingcharacteristics. It is noted that a color filter in accordance with thepresent invention is designed to do more than simply filter out the bluecomponent light from the LED chips. Instead the color filter isconfigured to take advantage of spectral opponency; namely thephenomenon wherein wavelengths from one portion of the spectrum excite aresponse, while wavelengths from another portion inhibit a response.

For example, recent studies have shown that spectral opponency resultsin certain wavelengths of light negating the melatonin suppressioncaused by blue light. As such, the inventors have discovered that bydesigning a color filter that filters some (i.e., not all) of the bluecomponent of the LED chips, while increasing the yellow component(yellow being the spectral opponent to blue), an LED lamp can bedesigned to maintain commercially acceptable color rendering properties,while minimizing the biological effects of the LED lamp. By minimizingthe biological effects (e.g., reducing melatonin suppression), the LEDlamp can provide relief for people who suffer from sleep disorders,circadian rhythm disruptions, and other biological system disruptions.

FIG. 3 is an exploded view of LED lamp 100, illustrating internalcomponents of the lamp. As shown, in addition to the componentsdescribed above, LED lamp 100 also includes at least a housing 115, aprinted circuit board (PCB) 117, one or more LED chips 200, a holder125, spring wire connectors 127, and screws 129.

PCB 117 includes dedicated circuitry to power, drive, and control one ormore LED chips 200. PCB 117 includes at least a driver circuit and apower circuit. The circuitry on PCB 117 serves as a means for drivingthe LED chips 200. In one embodiment the driver circuit is configured todrive LED chips 200 with a ripple current at frequencies greater than200 Hz. A ripple current at frequencies above 200 Hz is chosen to avoidbiological effects that may be caused by ripple currents at frequenciesbelow 200 Hz. For example, studies have shown that some individuals aresensitive to light flicker below 200 Hz, and in some instancesexperience aggravated headaches, seizures, etc.

As used herein, the term “LED chips” is meant to broadly encompass LEDdies, with or without packaging and reflectors, that may or may not betreated (e.g., with applied phosphors). In the embodiment shown,however, LED chips 200 are “white LED chips” having a plurality ofblue-pumped (about 465 nm) LED dies with a phosphor applied thereto. Inanother embodiment, LED chips 200 are white LED chips having a pluralityof blue-pumped (about 450 nm) LED dies with a phosphor applied thereto.In alternative embodiments, LED chips 200 employ a garnet basedphosphor, such as a Yttrium aluminum garnet (YAG) or dual-YAG phosphors,orthosilicate based phosphors, or quantum dots to create white light. Inone embodiment, LED chips 200 emit light having a color temperaturebetween about 2500K and about 2900K, and more preferably about 2700K.

FIGS. 4-7 are exploded views of portions of LED lamp 100. FIGS. 4-7illustrate how to assemble LED lamp 100. As shown in FIG. 4, base 110 isglued or crimped onto housing 115. PCB 117 is mounted within housing115. Insulation and/or potting compound (not shown) may be used tosecure PCB 117 within housing 115. Electrical leads (not shown) on PCB117 are coupled to base 110 to form the electrical input leads of LEDlamp 100.

As shown in FIG. 5, heat sink 120 is disposed about housing 115. Asshown in FIG. 6, two LED chips 200 are mounted onto heat sink 120, andmaintained in place by holder 125. While two LED chips 200 are shown,alternative embodiments may include any number of LED chips (i.e., oneor more). Screws 129 are used to secure holder 125 to heat sink 120.Screws 129 may be any screws known in the art (e.g., M2 plastitescrews). Spring wire connectors 127 are used to connect LED chips 200 tothe driver circuit on PCB 117. In an alternative embodiment, LED chips200 (with or without packaging) may be attached directly to heat sink120 without the use of holder 125, screws 129, or connectors 127. Asshown in FIG. 7, optic 130 is then mounted on and attached to heat sink120.

FIG. 8 illustrates an optimal transmission curve for a color filter inaccordance with one embodiment of the present invention. The inventorshave found that the transmission curve of FIG. 8 provides increasedspectral opponency, which minimizes biological effects, whilemaintaining a commercially acceptable color rendering index. Forexample, application of a color filter having the transmission curve ofFIG. 8 to LED lamp 100 results in a lamp having a color rendering indexabove 70, and more preferably above 80, and a color temperature betweenabout 2,700K and about 3,500K, and more preferably about 3,015K. In oneembodiment, LED lamp 100 produces no UV light. In one embodiment, LEDlamp 100 produces 400-800 lumens.

In one embodiment, the color filter is a ROSCOLUX #87 Pale Yellow Greencolor filter. In an alternative embodiment, the color filter has a totaltransmission of about 85%, a thickness of about 38 microns, and isformed of a deep-dyed polyester film.

In yet another embodiment, the color filter has transmission percentageswithin +/−10%, at one or more wavelengths, in accordance with thefollowing table:

Wavelength Transmission (%) 360 59 380 63 400 60 420 50 440 45 460 53480 75 500 78 520 79 540 78 560 77 580 74 600 71 620 67 640 63 660 61680 60 700 64 720 74 740 81

FIG. 10 illustrates an optimal transmission curve for a color filter inaccordance with one embodiment of the present invention. The inventorshave found that the transmission curve of FIG. 10 provides increasedspectral opponency, which minimizes biological effects, whilemaintaining a commercially acceptable color rendering index.

In one embodiment, the color filter is a ROSCOLUX #4530 CALCOLOR 30YELLOW color filter. In an alternative embodiment, the color filter hasa total transmission of about 75%, a thickness of about 50 microns, andis formed of a deep-dyed polyester film.

In yet another embodiment, the color filter has transmission percentageswithin +/−10%, at one or more wavelengths, in accordance with thefollowing table:

Wavelength Transmission (%) 360 66 380 64 400 49 420 30 440 22 460 35480 74 500 81 520 84 540 85 560 85 580 85 600 86 620 86 640 86 660 86680 86 700 86 720 86 740 87

In still another embodiment, there is provided a biologically-correctedLED lamp, having a plurality of blue-pump LED chips. The LED chips mayhave a peak emission of about 450 nm. The lamp further includes a colorfilter configured to attenuate the 450 nm emission and provide apolychromatic output with peak emissions at: about 475 nm with an about25 nm half-peak width; about 500 nm with an about 30 nm half-peak width;and/or a peak between about 590 nm and about 625 nm with an about 20 nmhalf-peak width.

As used herein, the “means for increasing the spectral opponency of thelight output to limit the biological effect of the light output” shouldinclude the herein described embodiments of color filters, andequivalents thereto. For example, color filters with equivalenttransmission characteristics may be formed of absorptive or reflectivecoatings, thin-films, body-colored polycarbonate films, deep-dyedpolyester films, surface-coated films, etc. In an alternativeembodiment, pigment may be infused directly into the optic in order toproduce the transmission filter effects. In another alternativeembodiment, phosphors and/or quantum dots may be employed as “means forincreasing the spectral opponency of the light output to limit thebiological effect of the light output.” For example, a combination ofgreen converted and red converted phosphors can applied to the blue LEDpump to create the light spectrum depicted in Curve E of FIG. 9(discussed below).

Color filters having the transmission curve shown in, for example, FIGS.8 and 10, and equivalents thereto, also minimizes thecircadian-to-photopic ratio. As such, the color filters describedherein, and equivalents thereto, serve as a means for minimizing thecircadian-to-photopic ratio of a lamp. The term “a circadian-to-photopicratio” is defined as “the ratio of melatonin suppressive light to totallight output.” More specifically, the circadian-to-photopic ratio may becalculated as a unit-less ratio defined as:

$\frac{\rho}{\phi}\mspace{14mu}{where}$ ρ = K₁∫₃₈₀⁷⁸⁰P_(λ)C(λ)δ λand  where ϕ = K₂∫₃₈₀⁷⁸⁰P_(λ)V(λ)δ λ

In one embodiment, K₁ is set to equal K₂. P_(λ) is the spectral powerdistribution of the light source. C(λ) is the circadian function(presented in the above referenced Figueiro et al. and Rea et al.publications). V(λ) is the photopic luminous efficiency function(presented in the above referenced Figueiro et al. and Rea et al.publications). In one embodiment, the LED lamp produced in accordancewith the present invention has a circadian-to-photopic ratio below about0.10, and more preferably a circadian-to-photopic ratio below about0.05, and most preferably a zero circadian-to-photopic ratio (i.e., nomelatonin suppressive light is produced, although the lamp is generatinga measurable amount of total light output). By way of contrast, theinventors have found the circadian-to-photopic ratio of a 2856Kincandescent source to be about 0.138; of a white LED to be about 0.386;and of a fluorescent light source to be about 0.556.

FIG. 9 illustrates the light spectra of conventional light sources incomparison to the predicted melatonin suppression action spectrum, asillustrated in FIG. 1, and further including the light spectrum of anLED lamp in accordance with one embodiment of the present invention(Curve E). As shown by Curve E, a color filter in accordance with thepresent invention does not necessarily filter out the entire bluecomponent light of the LED chips. In fact, Curve E shows a bluecomponent spike at about 450 nm. However, the color filter minimizes thebiological effects of the light by compensating with spectral opponency.In other words, the color filter is designed to increase the yellowcomponent light, which is the spectral opponent of blue light. As such,the resulting light source can maintain commercially acceptable colorrendering properties, while minimizing biological effects.

EXAMPLES

The following paragraphs serve as example embodiments of theabove-described systems. The examples provided are prophetic examples,unless explicitly stated otherwise.

Example 1

In one example, there is provided a biologically-corrected LED lamp,comprising a housing; a driver circuit disposed within the housing; aplurality of LED chips electrically coupled to and driven by the drivercircuit, wherein the plurality of LED chips produce a light output; andan optic element surrounding the plurality of LED chips. The opticelement has a color filter applied thereto. The color filter isconfigured to increase spectral opponency to thereby decrease amelatonin suppressive effect of the light output of the plurality of LEDchips. The color filter may have a total transmission of about 75%, athickness of about 50 microns, and is formed of a deep-dyed polyesterfilm.

In one embodiment, the lamp further comprises a heat sink disposed aboutthe housing.

In one embodiment, the plurality of LED chips are blue-pumped white LEDchips. In an embodiment, light output of the plurality of LED chips hasa color temperature between about 2,500K and about 2,900K. In anotherembodiment, the light output of the plurality of LED chips has a colortemperature of about 2,700K.

In one embodiment, the lamp has a color rendering index above 70, and acolor temperature between about 2,700K and about 3,500K.

Example 2

In another example, there is provided a biologically-corrected LED lamp,comprising a housing; a driver circuit disposed within the housing; aplurality of LED chips electrically coupled to and driven by the drivercircuit, wherein the plurality of LED chips produce a light output; andan optic element surrounding the plurality of LED chips. The opticelement has a color filter applied thereto. The color filter isconfigured to increase spectral opponency to thereby decrease amelatonin suppressive effect of the light output of the plurality of LEDchips. The color filter is a ROSCOLUX #4530 CALCOLOR 30 YELLOW colorfilter.

Example 3

In an example, there is provided a biologically-corrected LED lamp,having a color rendering index above 70 and a color temperature betweenabout 2,700K and about 3,500K, wherein the lamp produces a spectralpower distribution that increases spectral opponency to thereby minimizemelatonin suppression. The lamp comprises: a base; a housing attached tothe base; a power circuit disposed within the housing and havingelectrical leads attached to the base; a driver circuit disposed withinthe housing and electrically coupled to the power circuit; a heat sinkdisposed about the housing; a plurality of LED chips electricallycoupled to and driven by the driver circuit, wherein the plurality ofLED chips are coupled to the heat sink, wherein the plurality of LEDchips are blue-pumped white LED chips that produce light having a colortemperature of about 2,700K, and wherein the driver circuit isconfigured to drive the plurality of LED chips with a ripple current atfrequencies greater than 200 Hz; and optic diffusing element mounted onthe heat sink and surrounding the plurality of LED chips, wherein theoptic diffusing element has a color filter applied thereto, and whereinthe color filter is configured to increase spectral opponency to therebydecrease a melatonin suppressive effect of a light output from theplurality of LED chips. The color filter has a transmission of about 22%at a wavelength of about 440 nm, a transmission of about 35% at awavelength of about 460 nm, a transmission of about 74% at a wavelengthof about 480 nm, a transmission of about 85% at a wavelength of about560 nm, a transmission of about 85% at a wavelength of about 580 nm, anda transmission of about 86% at a wavelength of about 600 nm.

Example 4

In another example, there is provided a method of minimizing abiological effect produced by a white LED lamp, wherein the LED lampincludes a housing, a driver circuit disposed within the housing, aplurality of LED chips electrically coupled to and driven by the drivercircuit, wherein the plurality of LED chips produce a light output, andan optic element surrounding the plurality of LED chips. The methodcomprises applying to the optic element a color filter having atransmission of about 22% at a wavelength of about 440 nm, atransmission of about 35% at a wavelength of about 460 nm, atransmission of about 74% at a wavelength of about 480 nm, atransmission of about 85% at a wavelength of about 560 nm, atransmission of about 85% at a wavelength of about 580 nm, and atransmission of about 86% at a wavelength of about 600 nm. The methodmay also comprise configuring the driver circuit to drive the LED chipwith a ripple current at frequencies greater than 200 Hz.

Example 5

In yet another example, there is provided a method of increasingspectral opponency of an LED lamp comprising: applying to the LED lamp aROSCOLUX #4530 CALCOLOR 30 YELLOW color filter.

CONCLUSION

The foregoing description of the invention has been presented forpurposes of illustration and description. It is not intended to beexhaustive or to limit the invention to the precise form disclosed.Other modifications and variations may be possible in light of the aboveteachings. The embodiments were chosen and described in order to bestexplain the principles of the invention and its practical application,and to thereby enable others skilled in the art to best utilize theinvention in various embodiments and various modifications as are suitedto the particular use contemplated. It is intended that the appendedclaims be construed to include other alternative embodiments of theinvention; including equivalent structures, components, methods, andmeans.

It is to be appreciated that the Detailed Description section, and notthe Summary and Abstract sections, is intended to be used to interpretthe claims. The Summary and Abstract sections may set forth one or more,but not all exemplary embodiments of the present invention ascontemplated by the inventor(s), and thus, are not intended to limit thepresent invention and the appended claims in any way.

What is claimed is:
 1. A biologically-corrected light-emitting diode(LED) lamp, comprising: a housing; a driver circuit disposed within thehousing; a plurality of LED chips electrically coupled to and driven bythe driver circuit, wherein the plurality of LED chips produce a lightoutput; and an optic element operable to receive light from theplurality of LED chips, wherein the optic element has a color filterapplied thereto, wherein the color filter is configured to increasespectral opponency to thereby decrease a biological effect of the lightoutput of the plurality of LED chips, and wherein the color filter has atotal transmission of about 75%.
 2. A biologically-corrected lampaccording to claim 1 wherein the color filter is configured to attenuatethe 450 nanometers emission and provide a polychromatic output with peakemissions at least one of about 475 nanometers with an about 25nanometers half-peak width, about 500 nanometers with an about 30nanometers half-peak width, and between about 590 nanometers and about625 nanometers with an about 20 nanometers half-peak width.
 3. Abiologically-corrected LED lamp according to claim 1 wherein the lampproduces approximately no ultraviolet light.
 4. A biologically-correctedLED lamp according to claim 1 wherein the lamp has a color renderingindex above about
 80. 5. A biologically-corrected LED lamp according toclaim 1, wherein the lamp has a color temperature within the range fromabout 2,500 Kelvin to about 3,500 Kelvin.
 6. A biologically-correctedlight-emitting diode (LED) lamp having a color rendering index above 80and a color temperature between within the range from about 2,500 Kelvinto about 3,500 Kelvin wherein the lamp produces a spectral powerdistribution that increases spectral opponency to thereby minimizemelatonin suppression, the lamp comprising: a base; a housing attachedto the base; a power circuit disposed within the housing and havingelectrical leads attached to the base; a driver circuit disposed withinthe housing and electrically coupled to the power circuit; a heat sinkdisposed about the housing; a plurality of LED chips electricallycoupled to and driven by the driver circuit; and an optic diffusingelement mounted on the heat sink and surrounding the plurality of LEDchips; wherein the plurality of LED chips are thermally coupled to theheat sink; wherein the plurality of LED chips are blue-pumped white LEDchips that produce light having a color temperature of between about2,700 Kelvin and 3500 Kelvin; wherein the driver circuit is configuredto drive the plurality of LED chips with a ripple current at frequenciesgreater than about 200 Hz; wherein the optic diffusing element has acolor filter applied thereto; wherein the color filter is configured toincrease spectral opponency to thereby decrease a melatonin suppressiveeffect of a light output from the plurality of LED chips; and whereinthe color filter has a total transmission of between about 65% and 85%.7. A biologically-corrected LED lamp according to claim 6 wherein thecolor temperature is greater than 3500K.
 8. A biologically-corrected LEDlamp according to claim 6 wherein the color filter has a transmission ofbetween about 12% and 32% at a wavelength of about 440 nanometers, atransmission of between about 25% and 45% at a wavelength of about 460nanometers, a transmission of between about 64% and 84% at a wavelengthof about 480 nanometers, a transmission of between about 75% and 100% ata wavelength of about 560 nanometers, a transmission of between about75% and 100% at a wavelength of about 580 nanometers, and a transmissionof between about 76% and 100% at a wavelength of about 600 nanometers.9. A biologically-corrected LED lamp according to claim 6 wherein thecolor filter comprises a surface-coated film on a portion of the opticdiffusing element.
 10. A biologically-corrected LED lamp according toclaim 6 wherein the color filter comprises one or more of phosphors andquantum dots.
 11. A biologically-corrected LED lamp according to claim 9wherein the one or more phosphors or quantum dots are infused directlyinto the optic.
 12. A biologically-corrected LED lamp according to claim10 wherein the infused optic comprises a polycarbonate.
 13. Abiologically-corrected LED lamp according to claim 6 wherein acombination of green converted phosphors and red converted phosphors areapplied to the blue LED pump.
 14. A method of minimizing a biologicaleffect produced by a white light-emitting diode (LED) lamp, wherein theLED lamp includes a housing, a driver circuit disposed within thehousing, a plurality of LED chips electrically coupled to and driven bythe driver circuit, wherein the plurality of LED chips produce a lightoutput, and an optic element surrounding the plurality of LED chips, themethod comprising the step of applying to the optic element a colorfilter having a transmission of between about 12% and 32% at awavelength of about 440 nanometers, a transmission of between about 25%and 45% at a wavelength of about 460 nanometers, a transmission ofbetween about 64% and 84% at a wavelength of about 480 nanometers, atransmission of between about 75% and 100% at a wavelength of about 560nanometers, a transmission of between about 75% and 100% at a wavelengthof about 580 nanometers, and a transmission of between about 76% and100% at a wavelength of about 600 nanometers.
 15. A method according toclaim 14 further comprising the step of configuring the driver circuitto drive the LED chip with a ripple current at frequencies greater than200 Hz.